Keir E. Novik scite author profile

We investigate the dynamical behavior of binary fluid systems in two dimensions using dissipative particle dynamics. We find that following a symmetric quench the domain size R(t) grows with time t according to two distinct algebraic laws R(t) ∼ t n : at early times n = 1 2 , while for later times n = 2 3 .Following an asymmetric quench we observe only n = 1 2 , and if momentum conservation is violated we see n = 1 3 at early times. Bubble simulations confirm the existence of a finite surface tension and the validity of Laplace's law.Our results are compared with similar simulations which have been performed previously using molecular dynamics, lattice-gas and lattice-Boltzmann automata, and Langevin dynamics. We conclude that dissipative particle dynamics is a promising method for simulating fluid properties in such systems.

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Using Dissipative Particle Dynamics to Model Binary Immiscible Fluids

Novik

Coveney

1997

Int. J. Mod. Phys. C

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Spinodal decomposition of off-critical quenches with a viscous phase using dissipative particle dynamics in two and three spatial dimensions

Novik

Coveney

2000

Phys. Rev. E

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Erratum: Computer simulations of domain growth and phase separation in two-dimensional binary immiscible fluids using dissipative particle dynamics [Phys. Rev. E 54, 5134 (1996)]

Coveney¹,

Novik²

1997

Phys. Rev. E

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Large-scale molecular dynamics simulation of DNA: implementation and validation of the AMBER98 force field in LAMMPS

Grindon

Harris

Evans

et al. 2004

Philosophical Transactions of the Royal Society of London. Seri

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Molecular modelling played a central role in the discovery of the structure of DNA by Watson and Crick. Today, such modelling is done on computers: the more powerful these computers are, the more detailed and extensive can be the study of the dynamics of such biological macromolecules. To fully harness the power of modern massively parallel computers, however, we need to develop and deploy algorithms which can exploit the structure of such hardware. The Large-scale Atomic/Molecular Massively Parallel Simulator (LAMMPS) is a scalable molecular dynamics code including long-range Coulomb interactions, which has been specifically designed to function efficiently on parallel platforms. Here we describe the implementation of the AMBER98 force field in LAMMPS and its validation for molecular dynamics investigations of DNA structure and flexibility against the benchmark of results obtained with the long-established code AMBER6 (Assisted Model Building with Energy Refinement, version 6). Extended molecular dynamics simulations on the hydrated DNA dodecamer d(CTTTTGCAAAAG)(2), which has previously been the subject of extensive dynamical analysis using AMBER6, show that it is possible to obtain excellent agreement in terms of static, dynamic and thermodynamic parameters between AMBER6 and LAMMPS. In comparison with AMBER6, LAMMPS shows greatly improved scalability in massively parallel environments, opening up the possibility of efficient simulations of order-of-magnitude larger systems and/or for order-of-magnitude greater simulation times.

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Keir E. Novik

Computer simulations of domain growth and phase separation in two-dimensional binary immiscible fluids using dissipative particle dynamics

Using Dissipative Particle Dynamics to Model Binary Immiscible Fluids

Spinodal decomposition of off-critical quenches with a viscous phase using dissipative particle dynamics in two and three spatial dimensions

Erratum: Computer simulations of domain growth and phase separation in two-dimensional binary immiscible fluids using dissipative particle dynamics [Phys. Rev. E 54, 5134 (1996)]

Large-scale molecular dynamics simulation of DNA: implementation and validation of the AMBER98 force field in LAMMPS

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